Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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PARABOLIC LED LAMP
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to the field of LED lighting technology, more
particularly, to a parabolic LED lamp.
2. Description of the Related Art
As green lighting, LED (light emitting diode) lamp has been paid
more and more attention due to its high brightness, energy-saving and
environmental protection, good performance of shock and vibration
resistance, long life, high efficiency of light and other apparent
advantages. The light emitting and light distributing features of LED light
source accord with the radiation characteristics of Lambertian light
emitter in the case of not being reflected by an anti-halo or refracted by a
lens, such emitters are also known as the cosine emitters. The
illumination intensity of the light emitted from LED light source is very
nonuniform and we can't control the light emitted from LED light source
without light distribution.
In order to obtain more uniform lighting effects, generally using one
or more reflection by reflective lampshade to distribute light emitted from
the LED light source to ensure uniform illumination. However, the
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reflective type LED lamps after a reflection, the light emitted from which
is not fully projected onto the reflective lampshade, some of the light
emits directly outside the lamps without being reflected, which is not
conducive to adjust the angle of the emergent ray and the distribution of
the light intensity of LED lamps. The structure of lamps of which the
light emitted from the LED light source emitting after multiple reflections
is more complex in structure, and the production cost is higher, which
additionally increases the production cost of the LED lamps and does not
conducive to promote the use of LED lamps.
In addition, the formation of the beam angle of existing LED
parabolic aluminum reflector (PAR) lamps uses COB (the cost of COB
(Chip On Board) light source is higher than SMD (Surface Mounted
Devices) light source) as a light source to achieve the predetermined
beam angle of the product by a lens made from a multi-refraction
reflective cup or PMMA, to ensure the distribution of light intensity in
effective irradiated areas. The disadvantages thereof are the defects
such as black and yellow spots, the light emitting area is small through
the COB light source and the light exiting area is small through the
limitation of angle by a reflective panel, which cause a small irradiated
area in equidistance position, and phenomenon of nonuniform
distribution of light after multiple refractions by the reflective cup. And,
PMMA is easy to deteriorate to decrease the light transmittance, so that
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the light of lamps fades large. The light intensity and brightness is higher
in the light focused center, central light intensity free falls into effective
dark space when greater than 100. At the same time during the product
assembling, the center point of the COB light source and the reflective
cup must be the same; if not, the beam angle of which appears a
phenomenon of not a parabola.
SUMMARY OF THE INVENTION
Aimed at the above-mentioned problems existing in the prior art,
this invention seeks to provide a parabolic LED lamp with simple
structure and uniform light intensity.
The specific technical solution is as follow:
a parabolic LED lamp having such characteristics, comprising: a
revolving-body-shaped lamp body, a lamp base covered and installed on
one end of the lamp body, an arc lens installed on another end of the lamp
body, an LED light source configured toward the arc lens, and a drive
internally configured in the lamp body and connected to the lamp base
and the LED light source; and further comprising a parabolic reflective
cup embedded and installed in the lamp body and an opening of the
parablic reflective cup directly facing the arc lens; and the LED light
source is installed in a bottom of the parabolic reflective cup; wherein the
inner wall of the arc lens formed with a plurality of first lens areas and
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second lens areas spaced apart, the first lens areas uniformly distributed
with a plurality of small hexagonal lenses with a same specifications, the
second lens areas uniformly distributed with a plurality of small rhombic
lenses with a same specifications.
In the above-mentioned parabolic LED lamp, wherein the first lens
areas and the second lens areas all extend spirally radially outward from a
center of the arc lens.
In the above-mentioned parabolic LED lamp, wherein the arc lens
and the end of the lamp body are cemented by adhesive.
In the above-mentioned parabolic LED lamp, wherein, the arc lens is
clamped with the end of the lamp body.
In the above-mentioned parabolic LED lamp, wherein the arc lens is
embedded with the end of the lamp body.
In the above-mentioned parabolic LED lamp, wherein the arc lens
and the end of the lamp body are occluded in the form of mechanical
curling.
In the above-mentioned parabolic LED lamp, wherein a rim of the
parabolic reflective cup and the arc lens are cemented by adhesives.
In the above-mentioned parabolic LED lamp, wherein the rim of the
parabolic reflective cup and the arc lens are connected upside down.
In the above-mentioned parabolic LED lamp, wherein in a rectilinear
direction from the lamp base to the arc lens, a diameter of the lamp body
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gradually increases.
In the above-mentioned parabolic LED lamp, wherein the center of
the lamp body has an arc portion projected outward.
In the above-mentioned parabolic LED lamp, wherein the parabolic
reflective cup is spinning and stamping moulded by aluminum.
In the above-mentioned parabolic LED lamp, wherein the LED light
source and the bottom of the parabolic reflective cup are detachably
connected by a plurality of threaded fasteners; and the plurality of
threaded fasteners are distribute as an annular array around the axis of the
lamp body.
The positive effects of the above-mentioned technical solution are:
In the parabolic LED lamp of above-mentioned structure, parts of
the beams emitted from the LED light source directly emit to the arc lens;
and, another parts of the beams emitted from the LED light source gather
and reflect by the arc sidewall of the parabolic reflective cup to form a
certain beam angle to the arc lens, the small hexagonal lenses and the
small rhombic lenses of the arc lens then uniformly extend and refract the
received directly emitted beams and reflected beams outward, under the
combination effect of the optical reflection of the parabolic reflective cup
and the optical refraction of the arc lens; the angle of the emergent ray of
the parabolic LED lamp can be adjust to a desired state, and the light
intensity of the parabolic LED lamp can be more soft and uniform. In
addition, the light fall within an effective angle of the light emitted from
the parabolic LED
lamp has no ladder phenomenon.
Further, the parabolic LED lamp with above-mentioned structure is only
configured
with a single parabolic reflective cup, and light beams emitted from the LED
light source
pass only one reflection, which does not make the structure of LED lights
complicated, and
effectively controls the manufacturing cost of LED lights.
Accordingly, in one aspect, the present invention resides in a parabolic LED
lamp,
comprising: a lamp body, showing a revolving-body-shape; a lamp base, covered
and
installed on one end of the lamp body; an arc lens, installed on another end
of the lamp body;
an LED light source, configured toward the arc lens; and a drive, internally
configured in the
lamp body and connected to the lamp base and the LED light source; wherein the
parabolic
LED lamp further comprises: a parabolic reflective cup, embedded and installed
in the lamp
body, and an opening of the parabolic reflective cup directly facing the arc
lens; and the LED
light source is installed in a bottom of the parabolic reflective cup; wherein
an inner wall of
the arc lens is formed with a plurality of first lens areas and second lens
areas spaced apart;
the first lens areas uniformly distributed with a plurality of small hexagonal
lenses with a
same specification, the second lens areas uniformly distributed with a
plurality of small
rhombic lenses with a same specification; and wherein the first lens areas and
the second
lens areas all extend spirally radially outward from a center of the arc lens.
BRIEF DESCRIPTIONS OF THE DRAWINGS
Figure 1 is a semi-sectional view of an embodiment of a parabolic LED lamp of
the
invention.
Figure 2 is an explosive view of an embodiment of a parabolic LED lamp of the
invention.
Figure 3 is an enlarged view of the corresponding part of letter A in Figure
1.
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Figure 4 is a structure diagram of an embodiment of the arc lens of a
parabolic LED
lamp of the invention.
In the drawings: 1, lamp body; 11, arc portion; 2, lamp base; 3, arc lens; 31,
small
hexagonal lens; 32, small rhombic lens; 4, parabolic reflective cup; 41,
bottom of the cup;
42, rim of the cup; 5, LED light source; 6, drive; 7, threaded fasteners.
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DETAILED DESCRIPTION
In order to make the technical means, the technical features, the
purpose and the effects achieved of the invention easy to understand, the
following embodiments with reference to the accompanying drawings 1-4
elaborate the technical solution provided in the invention, however the
following content is not a limitation of the invention.
Figure 1 is a semi-sectional view of an embodiment of a parabolic
LED lamp; Figure 2 is an explosive view of an embodiment of a
parabolic LED lamp. As shown in figure 1 and figure 2, the parabolic
LED lamp provided in the embodiment comprises: lamp body 1, lamp
base 2, arc lens 3, parabolic reflective cup 4, LED light source 5, and
drive 6.
Specifically, the lamp body 1 shows a revolving-body-shape, and is
injection-moulded by heat sink materials. One end of the lamp body 1 is
covered and installed with a lamp base 2, which can be one of screw type
or bayonet type. The other end of the lamp body 1 is installed with an arc
lens 3, which is hot injection-moulded by glasses. A parabolic reflective
cup 4 is embedded and installed in the lamp body 1, and the opening of
which directly faces the arc lens 3. The LED light source 5 is installed
in the bottom 41 of the parabolic reflective cup 4 and toward the arc lens
3. A drive 6 is connected to the lamp base 2 and the LED light source
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is internally configured in the lamp body 1.
Figure 4 is a structure diagram of an embodiment of the arc lens of a
parabolic LED lamp of the invention. As shown in figure 1 and figure 4,
the inner wall of the arc lens 3 is formed with a plurality of first lens
areas
and second lens areas spaced apart; the first lens areas uniformly are
distributed with a plurality of small hexagonal lenses 31 with a same
specifications, the second lens areas are uniformly distributed with a
plurality of small rhombic lenses 32 with a same specifications. In
addition, as a preferred embodiment, the first lens areas and the second
lens areas all extend spirally radially outward from a center of the arc lens
3.
It should be noted that, in this embodiment, since the seamed edges
of the small hexagonal lenses 31 and the small rhombic lenses 32 are all
transition-connected by an arc; therefore, when observing the arc lens
from outside, the shape of the small hexagonal lenses 31 and the small
rhombic lenses 32 are approximately circular. In addition, the size and
density of the small hexagonal lenses 31 and the small rhombic lenses 32
all can be properly adjusted according to dimming needs. Of course, as
a modified embodiment, the inner wall of the arc lens 3 can also be
densely distributed with a plurality of small circular lenses.
Figure 3 is an enlarged view of the corresponding part of letter A in
Figure 1. As shown in figure 1 and figure 3, further, in this embodiment,
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as a preferred embodiment, the arc lens 3 and the end of the lamp body 1
are cemented by adhesive. Namely, the arc lens 3 and the end of the
lamp body 1 are connected in a fixed way.
Of course, the arc lens 3 and the end of the lamp body 1 can also be
connected in a detachable way; as another preferred embodiment, the arc
lens 3 is clamped with the end of the lamp body 1 in the form of
combining snaps and necks.
As another preferred embodiment, the arc lens 3 is embedded with
the end of the lamp body 1.
As another preferred embodiment, the arc lens 3 and the end of the
lamp body 1 are occluded in the form of mechanical curling.
Further, in order to prevent the distance changing between the LED
light source 5 and the arc lens 3 caused by shaking of the parabolic
reflective cup 4; as a preferred embodiment, the rim 42 of the parabolic
reflective cup 4 and the arc lens 3 are cemented by adhesive. Of course,
the rim 42 of the parabolic reflective cup 4 and the arc lens 3 can also be
connected in a detachable way, for example, the rim of the parabolic
reflective cup and the arc lens are connected upside down.
Further, in order to make the parabolic LED lamp have a good beam
angle;, as a preferred embodiment, in the rectilinear direction from the
lamp base 2 to the arc lens 3, the diameter of the lamp body 1 gradually
increases. In addition, the center (i.e. near the bottom 41 portion of the
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parabolic reflective cup 4) of the lamp body 1 has an arc portion 11
projected outward.
Further, in order to be able to carry out rapid cooling to LED light
source 5, and considering the manufacturing cost and weight of the
parabolic reflective cup 4, as a preferred embodiment, the parabolic
reflective cup 4 is spinning and stamping moulded by aluminum.
As shown in figure 2, further, as a preferred embodiment, the LED
light source 5 and the bottom 41 of the parabolic reflective cup 4 are
detachably connected by a plurality of threaded fasteners 7; wherein the
threaded fasteners 7 can be screws or bolts. And, more preferably, the
threaded fasteners 7 are distributed as an annular array around the axis of
the lamp body 1.
As shown in figure 1, the dotted lines and arrows indicate the
direction of light propagation. In this embodiment, the angle of the light
beam emitted from the LED light source 5 is 125 , wherein parts of the
beams emitted from the LED light source 5 directly emit to the arc lens 3;
and, the other parts of the beams emitted from the LED light source 5 are
gathered into 25 angle by the arc sidewall of the parabolic reflective cup
4 and reflect to the arc lens 3, the small hexagonal lenses 31 and the small
rhombic lenses 32 of the arc lens 3 then uniformly extend and refract the
received direct beams and reflected beams outward in a 45 angle, thus
under the combination effect of the optical reflection of the parabolic
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reflective cup 4 and the optical refraction of the arc lens 3, the angle of
the emergent ray of the parabolic LED lamp can be adjust to the best state,
and the light intensity of the parabolic LED lamp can be more soft and
uniform.
In this embodiment, the emitting angle of the above-mentioned LED
light source 5, the gathering angle of light beams of the parabolic
reflective cup 4, the refracting angle of light beams of the arc lens 3 are
preferred values. Of course, in the parabolic LED lamp provided in the
invention, the emitting angle of the LED light source, the gathering angle
of light beams of the parabolic reflective cup and the refracting angle of
light beams of the arc lens can be adjusted accordingly according to the
design purpose.
The foregoing is only the preferred embodiments of the invention,
not thus limiting embodiments and scope of the invention, those skilled in
the art should be able to realize that the schemes obtained from equivalent
substitution and obvious changes using the content of specification and
figures of the invention are within the scope of the invention.
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